Method and apparatus to provide temporary peak power from a switching regulator

ABSTRACT

Various techniques directed to providing temporary peak power from a switching regulator are disclosed. In one aspect, a switching regulator includes a switch that is to be coupled between a power supply input and an energy transfer element of the power supply. A controller is coupled to be responsive to a feedback signal to be received from an output of the power supply. The controller is coupled to switch the switch in response to the feedback signal to regulate the output of the power supply. An oscillator is coupled to provide an oscillating signal to the controller to determine a maximum switching frequency of the switch. The oscillating signal is coupled to oscillate at a first frequency under a first moderate load condition at the power supply output. The oscillating signal is coupled to oscillate at a second frequency under a second peak load condition at the power supply output.

REFERENCE TO PRIOR APPLICATION

This application is a continuation of and claims priority to U.S.application Ser. No. 12/125,839, filed May 22, 2008, now pending, whichis a continuation of U.S. application Ser. No. 11/805,725, filed May 23,2007, now U.S. Pat. No. 7,388,360, which is a continuation of U.S.application Ser. No. 10/981,959, filed Nov. 5, 2004, now U.S. Pat. No.7,239,119. U.S. application Ser. No. 12/125,839 and U.S. Pat. Nos.7,388,360 and 7,239,119 are hereby incorporated by reference.

BACKGROUND

1. Technical Field

The present invention relates generally to electronic circuits, and morespecifically, the invention relates to switched mode power supplies.

2. Background Information

Many types of electronic equipment use varying amounts of power innormal operation. The range of power demanded from a power supply can beextreme, extending for example from a few milliwatts to nearly 100watts. Large ranges of loading are common in equipment such as printers,digital video disc (DVD) recorders, and other products that requirerapid activation of mechanical motion. Typically, a moderate continuousoutput power is required for a long duration, for example when a DVDdisk is spinning continuously or the print head in a printer is movingacross a page. However, a maximum or peak output power is usuallyrequired for a relatively short duration and infrequently, for exampleto reverse the direction of a moving printer head or to spin a disk fromstartup to its rated speed. Equipment to amplify signals that have alarge dynamic range, such as music, for example, can demand power thatcovers a range of several orders of magnitude.

Designers of power supplies for these applications are challenged toprovide a wide range of power while conforming to conflictingrequirements of efficiency, size, and cost. Power supplies that candeliver the maximum or peak required power often require the use ofcomponents that are over rated for the continuous moderate power level.Efforts to meet the requirements for continuous moderate power and shortduration peak power from the same power supply usually lead to designsthat are larger, heavier, and more costly than necessary if the loadrange were limited.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention detailed illustrated by way of example and notlimitation in the accompanying Figures.

FIG. 1 is a functional block diagram of a power supply that may includea switching regulator in accordance with the teachings of the presentinvention.

FIG. 2 is a graph of a typical power demand for a switching regulator inaccordance with the teachings of the present invention.

FIG. 3 shows waveforms of the current in the switch of a switchingregulator for two switching frequencies in accordance with the teachingsof the present invention.

FIG. 4 is a graph of the maximum theoretical output power for aswitching regulator as a function of switching frequency in accordancewith the teachings of the present invention.

FIG. 5 shows graphs of power demand and corresponding switchingfrequency for one embodiment of a switching regulator in accordance withthe teachings of the present invention.

FIG. 6 shows graphs of power demand and an alternative correspondingswitching frequency for one embodiment of a switching regulator inaccordance with the teachings of the present invention.

FIG. 7 shows functional elements of one embodiment of a controller for aswitching regulator in accordance with the teachings of the presentinvention.

FIG. 8 shows another embodiment of a controller for a switchingregulator in accordance with the teachings of the present invention.

DETAILED DESCRIPTION

Embodiments of a power supply regulator that may be utilized in a powersupply are disclosed. In the following description, numerous specificdetails are set forth in order to provide a thorough understanding ofthe present invention. It will be apparent, however, to one havingordinary skill in the art that the specific detail need not be employedto practice the present invention. Well-known methods related to theimplementation have not been described in detail in order to avoidobscuring the present invention.

Reference throughout this specification to “one embodiment” or “anembodiment” means that a particular feature, structure, orcharacteristic described in connection with the embodiment is includedin at least one embodiment of the present invention. Thus, theappearances of the phrases “in one embodiment” or “in an embodiment” invarious places throughout this specification are not necessarily allreferring to the same embodiment. Furthermore, the particular features,structures, or characteristics may be combined in any suitable manner inone or more embodiments.

FIG. 1 shows a functional block diagram of a power supply that mayinclude an embodiment of a power supply regulator in accordance with theteachings of the present invention. The topology of the power supplyillustrated in FIG. 1 is known as a flyback regulator. It is appreciatedthat there are many topologies and configurations of switchingregulators, and that the flyback topology shown in FIG. 1 is provided toillustrate the principles of an embodiment of the present invention thatmay apply also to other types of topologies in accordance with theteachings of the present invention. The power supply in FIG. 1 providesoutput power to a load 165 from an unregulated input voltage V_(IN) 105.The input voltage V_(IN) 105 is coupled to an energy transfer element T1125 and a switch S1 120. In the example of FIG. 1, the energy transferelement T1 125 is coupled between an input of the power supply and anoutput of the power supply. In the example of FIG. 1, the energytransfer element T1 125 is illustrated as a transformer with twowindings. A clamp circuit 110 is coupled to the primary winding of theenergy transfer element T1 125 to control the maximum voltage on theswitch S1 120. Switch S1 120 is switched on and off in response to oneembodiment of a controller circuit 145 in accordance with the teachingsof the present invention. In one embodiment, switch S1 120 is atransistor such as for example a power metal oxide semiconductor fieldeffect transistor (MOSFET). In one embodiment, controller 145 includesintegrated circuits and discrete electrical components. The operation ofswitch S1 120 produces pulsating current in the rectifier D1 130 that isfiltered by capacitor C1 135 to produce a substantially constant outputvoltage V_(O) or output current I_(O) at the load 165.

The output quantity to be regulated is U_(O) 150, that in general couldbe an output voltage V_(O), an output current I_(O), or a combination ofthe two. A feedback circuit 160 is coupled to the output quantity U_(O)150 to produce a feedback signal U_(FB) 155 that is an input to thecontroller 145. Another input to the controller 145 is the current sensesignal 140 that senses a current I_(D) 115 in switch S1 120. Any of themany known ways to measure a switched current, such as for example acurrent transformer, or for example the voltage across a discreteresistor, or for example the voltage across a transistor when thetransistor is conducting, may be used to measure current I_(D) 115.

In one embodiment, the controller 145 operates switch S1 120 tosubstantially regulate the output U_(O) 150 to its desired value. In oneembodiment, controller 145 includes an oscillator that definessubstantially regular switching periods. In one embodiment, regulationis accomplished by control of the conduction time of the switch within aswitching period. In each switching period, the fraction of theswitching period that the switch is closed is the duty ratio of theswitch. As will be discussed, one embodiment of the oscillator includedin controller 145 is configured to switch temporarily at a higherfrequency to accommodate temporary peak load conditions in accordancewith the teachings of the present invention.

The instantaneous output power P_(O) is the output voltage V_(O)multiplied by the output current I_(O). The load draws an output powerP_(O) that may change abruptly with time. FIG. 2 shows a graph of theoutput power demand of a typical load that may be accommodated by apower supply regulator in accordance with the teachings of the presentinvention. A distinguishing characteristic of the power requirement ofFIG. 2 is that the power is below a moderate level P_(M) most of thetime, going above P_(M) only occasionally, and rising to a much higherpeak level P_(PEAK) infrequently for short durations. In thisdescription, moderate power level P_(M) describes a level of outputpower that typically determines the thermal design of the power supply.Embodiments of a power supply in accordance with the teachings of thepresent invention are therefore designed to provide this moderate outputpower continuously, the various power supply components not exceedingtheir thermal ratings. In this description, therefore, this moderatepower level is much higher than very low output power operatingconditions, such as no-load and standby, which are also often requiredoperating conditions in power supply applications. For purposes of thisdisclosure, no-load is a condition where the output load of the powersupply is removed altogether. For purposes of this disclosure, standbyis a condition where the power supply output load is demanding a verylow power, for example in a DVD application where the DVD player iswaiting for a wake up signal from a remote controller. These no-load andstandby conditions are typically substantially lower than the moderatepower level, P_(M), as discussed here. As an example, in a DVD player,the peak output power requirement could be 20 watts, the continuousmoderate output power requirement could be 10 watts and a standby outputpower could be less than 0.5 watts. No-load and standby conditions mayrequire other long duration or continuous power supply operating modes,such as burst-modes and very low switching frequency, that areimplemented when the output power demand falls below a no-load orstandby power threshold, as will be known to one skilled in the art. Theduration of the peak power, P_(PEAK), demand is usually much less thanone second, and well below the thermal time constants of the electricalcomponents in the switching regulator. Therefore, in many applications,the ability of the switching regulator to deliver the peak power is notrestricted by the thermal limitations of the components. The regulator'speak power is limited by the maximum current of the components and bythe switching frequency.

Owing to the limitations of one or more components in the circuit, theswitches in all regulator designs have a maximum current limit I_(MAX)that they cannot exceed. Although all switches are inherently currentlimited, controllers in switching regulators usually prevent theswitches from exceeding the maximum current limit for the design.

FIG. 3 shows waveforms of the current I_(D) in the switch of a switchingregulator at two switching frequencies that correspond to the switchingperiods T1 and T2. Each current has the same maximum value I_(MAX). Theregulator operates at the same input voltage and output voltage for eachfrequency. Measurements of the waveforms show that operation of theregulator at the higher frequency provides about 60% more output powerthan operation at the lower frequency in the example illustrated in FIG.3.

The waveforms in FIG. 3 also illustrate two fundamental modes ofoperation, indicated by the different shapes of the current. Thetriangular shape in FIG. 3A is characteristic of discontinuousconduction mode (DCM), whereas the trapezoidal shape in FIG. 3B ischaracteristic of continuous conduction mode (CCM).

For a given maximum switch current I_(MAX), the maximum output power fora switching regulator is described by two simple functions of theswitching frequency:

$\begin{matrix}\begin{matrix}{P = {\left( \frac{P_{MAXDCM}}{f_{SMAXDCM}} \right)f_{S}}} & {0 \leq f_{S} \leq f_{SMAXDCM}}\end{matrix} & \left( {{Equation}\mspace{14mu} 1} \right) \\{and} & \; \\\begin{matrix}{P = {P_{MAXDCM}\left( {2 - \frac{f_{SMAXDCM}}{f_{S}}} \right)}} & {f_{S} \geq f_{SMAXDCM}}\end{matrix} & \left( {{Equation}\mspace{14mu} 2} \right)\end{matrix}$where f_(S) is the switching frequency, P_(MAXDCM) is the maximum powerin discontinuous conduction mode, and f_(SMAXDCM) is the maximumswitching frequency in discontinuous conduction mode that allows thecurrent in the switch to reach I_(MAX). The values of P_(MAXDCM) andf_(SMAXDCM) are determined by the values of the components in thecircuit, as will be understood by one skilled in the art. As such, theyare constants in the expressions.

FIG. 4 graphs the relationship between the theoretical maximum outputpower and the switching frequency of a switching regulator that has acurrent limited switch. The relationship is linear as described byEquation 1 in the region 410 between zero frequency and f_(SMAXDCM), themaximum frequency in discontinuous conduction mode. In the linear region410, the output power is directly proportional to the switchingfrequency f_(S). The maximum power in discontinuous conduction mode isP_(MAXDCM) at switching frequency f_(SMAXDCM).

In the region 420, at frequencies greater than f_(SMAXDCM), theregulator operates in continuous conduction mode. In continuousconduction mode, the power is hyperbolic as described by Equation 2,approaching a maximum of twice P_(MAXDCM). FIG. 4 shows that higherswitching frequency gives higher output power. Unfortunately, higherswitching frequency also gives higher losses since each switching cycleconsumes power. Therefore, in one embodiment of the present invention, aswitching regulator operates at the lowest switching frequency necessaryto deliver the required output power up to a maximum frequency, wherethe maximum frequency is varied depending on the output power demand,while meeting the constraints for size and cost.

In one embodiment, a switching regulator has a first maximum switchingfrequency when the output power is less than a moderate power P_(M), andhas a substantially higher second maximum frequency when the outputpower is higher than P_(M). FIG. 5 illustrates the relationship betweenoutput power and switching frequency in one embodiment of the invention.When the output power requirement of FIG. 5A goes above the moderatelevel P_(M), the switching frequency of FIG. 5B shifts from a low valuef_(S1) to a higher value f_(S2).

The shift in frequency can be one discrete step as illustrated in FIG.5B, or it can include multiple discrete steps that correspond tointermediate peak power levels, or it can change continuously to meetthe power demand as illustrated in FIG. 6B to meet the requirements ofspecial loads. A step shift between two frequencies is usually adequateto satisfy typical specifications. In one embodiment, the change inswitching frequency adjusts only the maximum power capability of theregulator and regulation of the output is accomplished by adjustment ofa different variable, such as the conduction time of the switch. Inanother embodiment the frequency shift can be varied up to a maximumvalue of f_(S2) to regulate the output when the output power requirementgoes above the moderate level P_(M), while the frequency is fixed at avalue of f_(S1) for load conditions between the moderate level P_(M) andthe substantially lower power of either no-load or standby. When theoutput power requirement is between the moderate level P_(M) and thesubstantially lower power of no-load or standby regulation of the outputmay be accomplished by adjustment of a variable other than switchingfrequency, such as the conduction time of the switch. In one embodiment,independent of the regulation technique used when the output powerrequirement goes above the moderate level P_(M), the frequency may bevaried to a value below f_(S1) when the output power requirement dropsbelow a lower threshold value that indicates operation either in no-loador standby condition. Other known techniques such as burst operation maybe employed to reduce power supply power consumption at no-load orstandby. When the output power requirement is above the lower thresholdindicating either a no-load or standby condition, regulation techniquescan include PWM current mode or voltage mode, on/off control or quasiresonant control as will be known to one skilled in the art.

The shift to the higher maximum frequency for infrequent and shortdurations provides the required peak output power capability without thepenalty of increased switching losses at moderate output power, andwithout the need to use larger components that are capable of highercurrents. Components and a switching frequency can therefore beoptimized to meet all requirements when the switching regulator providesthe moderate power P_(M). Then, the relationship in FIG. 4, described byEquation 1 and Equation 2, can be used to determine the increase infrequency required to provide the peak power P_(PEAK) from the designthat is optimized for the lower output power.

FIG. 7 shows one embodiment of a controller for a switching regulator inaccordance with the teachings of the present invention. Controller 700includes a pulse width modulator 720 that receives a current limitsignal 730, a clock signal 735, and feedback signal 740. The controlleroperates switch S1 715 of the switching regulator to regulate an outputU_(O) 760 to its desired value. In one embodiment, the controlleroperates switch S1 715 with a maximum switching frequency that issubstantially independent of the input of the power supply. In oneembodiment, controller 700 includes integrated circuits. In oneembodiment, controller 700 is included in an integrated circuit. In oneembodiment, controller 700 and switch S1 715 are integrated on amonolithic integrated circuit.

Current limit comparator 725 receives a current sense signal 705 that isproportional to the current in switch S1 715. When the current sensesignal 705 exceeds a reference I_(MAX) 710 that corresponds to a maximumpermissible current in switch S1 715, current limit signal 730 goes froma logic low level to a logic high level. A logic high level of thecurrent limit signal 730 forces pulse width modulator 720 to open switchS1. Pulse width modulator 720 can also open switch S1 715 to regulatethe output U_(o) even when the current limit signal 730 is low.

Clock signal 735 from oscillator 745 establishes the switching frequencyand the switching periods. The oscillator 745 changes the frequency ofthe clock signal 735 in response to the signal at a frequency shiftinput 750. The frequency shift input 750 receives a load demand signal755 that corresponds to the power requirement of the load. Power thatexceeds a moderate level increases the switching frequency. In variousembodiments, the load demand signal 755 may sense the load directly, orit may be an external system command that anticipates an increase inload. In one embodiment the load demand signal 755 may be generated bysensing the loss of feedback signal 740 or a magnitude of the feedbacksignal 740 for a predetermined period, depending on the particularembodiment, which would also indicate that the moderate power P_(M) loadcapabilities of the switching regulator have been exceeded. In thatcase, the load demand signal 755 may be combined with the feedbacksignal 740 to sense when the power demand has exceeded the moderatepower P_(M) load capabilities of the switching regulator.

FIG. 8 shows an embodiment of a controller 800 that does not receive anexternal load demand signal. Instead, the controller 800 senses thecurrent in the switch S1 815 to determine the load demand. Controller800 in FIG. 8 includes pulse width modulator 820 that receives a currentlimit signal 830, a clock signal 835, and a feedback signal 840. Thecontroller operates switch S1 815 of the switching regulator to regulatean output U_(O) 880 to its desired value.

Current limit comparator 825 receives a current sense signal 805 that isproportional to the current in switch S1 815. When the current sensesignal 805 exceeds a reference I_(MAX) 810 that corresponds to a maximumpermissible current in switch S1 815, current limit signal 830 goes froma logic low level to a logic high level, forcing pulse width modulator820 to open switch S1. Pulse width modulator 820 can open switch S1 815to regulate the output even when the current limit signal 830 is low.

Clock signal 835 from oscillator 845 establishes the switchingfrequency. The oscillator 845 changes the frequency of the clock signal835 in response to the signal at a frequency shift input 850. In theembodiment of FIG. 8, the frequency shifts between two values. Theswitching frequency is at its lower value when the frequency shiftsignal at frequency shift input 850 is at a logic low level. Theswitching frequency is at its upper value when the frequency shiftsignal is at a logic high level.

A peak load detect circuit 855 receives the current limit signal 830 andthe clock signal 835 to determine if the load requires more than amoderate level of power. One can select among many different techniquesto distinguish peak load from moderate load, depending on the particularregulator topology, control method, and nature of the load in accordancewith the teachings of the present invention. For example, the peak loaddetect circuit 855 can count the number of switching periods that arecurrent limited, or for example, the peak load detect circuit 855 canrespond to a particular sequence of switching periods that are currentlimited and not current limited.

When the peak load detect circuit 855 determines that there is a peakload event, the peak mode signal 860 changes from a logic low level tologic high level. An optional time limit circuit 865 can be used withAND gate 875 to restrict or limit the duration of time of the peak poweroutput. A time limit circuit may be employed to reduce the possibilityof damage to the regulator from a fault that demands a high load for anexcessive time. The time limit circuit 865 sets its output 870 to alogic high level when the peak mode signal 860 goes to a logic highlevel. The output 870 of the time limit circuit 865 goes to a logic lowlevel after the maximum permitted duration of a peak load event,returning the switching frequency to its lower value. In otherembodiments, other circuits may be employed to perform the function ofthe time limit circuit 865 in accordance with the teachings of thepresent invention.

In the foregoing detailed description, the methods and apparatuses ofthe present invention have been described with reference to a specificexemplary embodiment thereof. It will, however, be evident that variousmodifications and changes may be made thereto without departing from thebroader spirit and scope of the present invention. The presentspecification and figures are accordingly to be regarded as illustrativerather than restrictive.

1. A controller, comprising: a pulse width modulator coupled to receivea clock signal, wherein the pulse width modulator is to be coupled tocontrol a switch to regulate an output level of a power supplyresponsive to the clock signal; a current limit comparator having afirst input, a second input, and an output, wherein the first input isto be coupled to receive a current sense signal representative of acurrent through the switch, wherein the second input is coupled toreceive a reference signal, and wherein the output produces a currentlimit signal to indicate whether the current sense signal exceeds thereference signal; a peak load detect circuit coupled to receive thecurrent limit signal to determine if a load of the power supply requiresmore than a moderate level of power; and an oscillator coupled to thepulse width modulator to generate the clock signal, wherein the clocksignal has a first maximum frequency when the peak load detect circuitdetermines that the load of the power supply does not require more thana moderate level of power and wherein the clock signal has a secondmaximum frequency when the peak load detect circuit determines that theload of the power supply requires more than a moderate level of power.2. The controller of claim 1, wherein the current sense signal isproportional to the current through the switch.
 3. The controller ofclaim 1, wherein the reference signal corresponds to a maximumpermissible current in the switch.
 4. The controller of claim 1, whereinthe controller is included in an integrated circuit.
 5. The controllerof claim 1, wherein the controller and the switch are integrated on amonolithic integrated circuit.
 6. The controller of claim 1, wherein thepulse width modulator is further coupled to receive a feedback signalfrom the power supply and wherein a duty cycle of the pulse widthmodulator is responsive to the feedback signal.
 7. The controller ofclaim 1, wherein the pulse width modulator is further coupled to receivethe current limit signal and to open the switch if the current limitsignal indicates that the current sense signal exceeds the referencesignal.
 8. The controller of claim 1, wherein the second maximumfrequency is greater than the first maximum frequency.
 9. The controllerof claim 1, wherein a switching frequency of the pulse width modulatoris substantially constant when peak load detect circuit determines thatthe load of the power supply does not require more than the moderatelevel of power and when the load of the supply requires more than ano-load or standby amount of power.
 10. The controller of claim 1,wherein a switching frequency of pulse width modulator is varied up tothe second maximum frequency to regulate a power level at the output ofthe power supply when the peak load detect circuit determines that theload of the power supply requires more than the moderate level of power.11. The controller of claim 1, wherein a switching frequency of thepulse width modulator is substantially equal to the first maximumfrequency of the clock signal when the peak load detect circuitdetermines that the load of the power supply does not require more thanthe moderate level of power and wherein the switching frequency issubstantially equal to the second maximum frequency when the peak loaddetect circuit determines that the load of the power supply requiresmore than the moderate level of power.
 12. The controller of claim 1,wherein the peak load detect circuit is further coupled to receive theclock signal and wherein the peak load detect circuit is configured todetermine that the load of the power supply requires more than themoderate level of power by counting a number of switching periods thatare current limited.
 13. The controller of claim 1, wherein the peakload detect circuit is further coupled to receive the clock signal andwherein the peak load detect circuit is configured to determine that theload of the power supply requires more than the moderate level of powerby responding to a particular sequence of switching periods that arecurrent limited and not current limited.
 14. The controller of claim 1,further comprising a time limit circuit coupled between the peak loaddetect circuit and the oscillator to limit a duration of time that theoscillator generates the clock signal at the second maximum frequency.